EP0459980B1

EP0459980B1 - Flexible lance and drive system

Info

Publication number: EP0459980B1
Application number: EP89912715A
Authority: EP
Inventors: Steven K. Ruggieri; Stephen Jens; Robert Sykes
Original assignee: Electric Power Research Institute Inc
Current assignee: Electric Power Research Institute Inc
Priority date: 1989-02-22
Filing date: 1989-10-25
Publication date: 1995-04-19
Anticipated expiration: 2009-10-25
Also published as: KR970008137B1; EP0459980A1; JP2812521B2; WO1990009850A1; DE68922315D1; CA1311166C; DE68922315T2; EP0459980A4; US5036871A; ATE121525T1; KR920700787A

Abstract

A flexible lance and drive system (10) extends through manhole (12) into blow down lane (14) of a pressurized water reactor (PWR) steam generator secondary side assembly (16). The system (10) includes a support rail (18) passing through the manhole (12) and along the blow down lane (14). A transporter (20) is suspended for locomotion along the support rail (18). A flexible lance (24) extends through the transporter (20) and can be driven by the transporter into tube bundle (26) to a greater or lesser extent as required to observe and/or clean sludge deposits (28) within the tube bundle (26). High pressure hoses (34), nitrogen purge line (36) and Fiber optics cable (32) is supported by a spacerless hosebar structure (38). The hosebar structure (38) is integrally formed from a flexible plastic material in a single piece.

Description

The present invention relates generally to an improved form of the flexible lances and systems disclosed in the above related applications. More particularly, it relates to such a flexible lance and system in which performance of the lance and system is enhanced in the areas of strength and flexibility, durability, fluid delivery at high flow and pressure, access to a difficult to access geometry and locomotion within the difficult to access geometry.
The flexible lances and systems in the above related applications represent a substantial improvement in the art for accessing and cleaning a difficult to access geometry, such as in sludge removal on the secondary side of pressurized water reactor (PWR) steam generators in the nuclear power industry. However, certain elements of the designs disclosed in those applications and unforeseen characteristics of the steam generators and the sludge deposits in them resulted in less than optimum performance of those flexible lance and system designs, including strength, durability and flexibility of the flexible lance, the volume and pressure of water delivered through the lances and tight intertube clearance. In the previous designs, the systems performed their operations on the steam generators while positioned on the central blowdown pipe. This operation mode limited access to intertube columns near the manhole due to the length of the transporter. Viewing the "back side" of the tall sludge pile existing in the steam generator was difficult due to the low operating elevation of the system transporter.
FR-A-2 554 123 discloses a flexible lance and drive system in which the flexible member is formed from two parallel foil sheets in which the foil sheets are held in their parallel orientation by hooks and tops. A drive roller is used to engage one of the foil sheets to drive the flexible member through a mobile carriage. To press the foil sheet against the drive roller and feed the flexible member in a right angle bend through the mobile carriage, several sets of guide roller assemblies are required. In order to drive a substantial length of the flexible member into a tube bundle or other difficult to access geometry with the mechanism shown, considerable stresses and wearing friction would have to be imposed on the foil sheet.
According to the present invention, there is provided a system comprising, in combination, a flexible means for accessing a tube bundle, at least one fluid carrying hose extending along said flexible means for accessing, and a transporter for moving the flexible means in the tube bundle, characterised in that the flexible means for accessing comprises a plurality of separate, integrally formed hosebar supports, each comprising a pair of separate longitudinally extending shapes engaging the separate shapes of adjacent hosebar supports and together defining flexible, longitudinally extending strips and a bar joining the pair of shapes, the bar having at least one correspondingly positioned aperture with respect to apertures in bars of the adjacent hosebar supports, the at least one fluid carrying hose extending along the plurality of hosebar supports through the apertures of the plurality of bars, and a pair of flexible support members, each extending lengthwise through corresponding ones of each pair of engaging separate, longitudinally extending shapes.
Thus, the invention overcomes the problems of the prior art apparatus and provides a flexible lance with increased flexibility in its horizontal plane and increased stiffness in its vertical plane. Such a construction also enables the flexible lance to deliver an increased volume of cleaning fluid at an increased pressure. Furthermore, a system incorporating such a flexible lance is able to access portions of a difficult to access geometry that are located adjacent to an access opening to the geometry. Advantageously, such a system has increased durability as a result of its simplified construction.
Examples of embodiments of the present invention will now be described with reference to the drawings, in which:-

Figure 1 is a perspective view of a flexible lance and drive system in accordance with an embodiment of the invention in use.
Figure 2 is a side view of the flexible lance shown in Figure 1.
Figure 3 is a top view of the flexible lance of Figure 2.
Figure 4 is a front view of the flexible lance of Figures 2-3.
Figure 5 is a side cross-section view of a portion of the flexible lance and drive system of Figures 1-4.
Figure 6 is a schematic front view of the flexible lance and drive system of Figures 1-3 in use.

Turning now to the drawings, more particularly to Figure 1, there is shown a flexible lance and drive system 10 of this invention extending through manhole 12 into blow down lane 14 of a PWR steam generator secondary side assembly 16. The system 10 includes a support rail 18 passing through the manhole 12 and along the blow down lane 14. A transporter 20 is suspended for locomotion along the support rail 18. A flexible lance 24 extends through the transporter 20 and can be driven by the transporter into tube bundle 26 to a greater or lesser extent as required to observe and/or clean sludge deposits 28 within the tube bundle 26.
Details of the flexible lance 24 are shown in Figures 2-4. High pressure hoses 34, nitrogen purge line 36 and VideoProbe fiber optics cable 32 are supported by a plurality of spacerless hosebar structures 38. The hosebar structures 38 are integrally formed from a flexible plastic material, such as a hard nylon (available under the trademark Delrin) in a single piece. The hosebar structures include upper and lower, faceted, longitudinally extending separate faceted shapes 48 defining strips 40 and 42 enclosing flexible safety cables 44 and 46, which provide structural strength to the flexible lance 24. Each repeating faceted shape 48 of the strips 40 or 42 is connected to an opposing faceted shape 48 on the other strip 42 or 40 by a vertical bar 50. The vertical bars 50 have passages 52 through which the hoses 34 and line 36 pass. The vertical bars 50 define slots 54 beside the strips 40 and 42, which interact with sprocket wheels for driving the flexible lance 24 through the transporter 20.
End hosebar structure 38 is attached to a nozzle block 56 on the front of the flexible lance 24. The nozzle block 56 has a plurality of removable, precision machined, high pressure orifices 58 connected to the high pressure water hoses 34 to provide water jets 60 for removing the sludge deposits 28. The middle water jets 60 converge for maximum sludge removal effect. A nitrogen nozzle 62 is directed at lens 64 of VideoProbe camera system 66. The fiber optics cable 32 of the VideoProbe camera system 66 provides illumination from a remote light source for making an area adjacent to the nozzle block 56 inside the tube bundle 26 visible.
Details of the transporter 20 and the rail 18 to which it is attached for movement along the blown down tube 14 are shown in Figure 5. The transporter 20 has a barrel 70 in which the flexible lance 24 is carried along the blow down lane and through which the flexible lance 24 is driven into the tube bundle 26. A lance drive motor 72 is connected to turn sprocket wheels 74 for advancing and retracting the flexible lance 24 in the barrel 70. The barrel 70 can be pivoted on its longitudinal axis through about 120° in order to provide different orientations of the flexible lance within the tube bundle 26. Tilt drive motor 76 is connected to the barrel 70 through gears 78 for this purpose. Drive motor 80 is connected to drive gears 82 for propelling the transporter 20 along the rail 18. The rail 18 has an integral gear rack 84 which meshes with the gears 82 for this purpose. The electric motors 72, 76 and 80 are all equipped with proportional speed control. Emergency releases 85 and 87 of a conventional nature are provided for the lance drive motor 72 and tilt drive motor 76. An emergency release (not shown) is also provided for the drive motor 80. These emergency releases allow quick disconnection of the transporter 20 to minimize exposure of personnel to radiation should the transporter 20 become contaminated.
For sludge lancing and inspection, the transporter 20 is suspended from the geared support rail 18. For viewing flow slots and tube support plates, the support rail is inverted, and the transporter sits on top of the rail 18. The use of the support rail 18 means that the transporter 18 can be driven directly to a desired intertube gap 86 (Figure 1), without pausing at intervening intertube gaps 86. Because the transporter 20 does not engage the tubes 88 in the tube bundle 26 during its propulsion along the blow down lane 14, any potential marring of the tubes 88 caused by flexible lance systems which engage the tubes during their travel along the blow down lane is eliminated. Because the transporter 20 does not interact directly with the geometry of the tube bundle 26 for moving along the blow down lane 14, the system 10 can be used with other steam generator designs, with adaptation being accomplished primarily with software changes, rather than hardware changes.
Figure 6 schematically shows the positioning advantages obtained both during lancing with jets 60 and during inspection with the VideoProbe camera system 66. The elevation of the transporter 20 so that it is opposite the handhole 12 in the blow down lane 14 allows the flexible lance 24 to approach sludge deposits 28 of varying height angling down from the transporter 20, thus facilitating removal of the deposits 28. The elevation of the transporter 20 also allows the flexible lance 24 to be extended for observation behind the tallest sludge piles 28 likely to be encountered in practice.
The rail 18 also allows the flexible lance 24 to access the closest intertube gaps 86 to the hand hole 12. This is done by having the transporter 20 extend only part way through the handhole 12, with the nozzle block 56 opposite the intertube gap 86 it is desired to enter with the flexible lance 24.

Claims

A system (10) comprising, in combination, a flexible means (24) for accessing a tube bundle (26), at least one fluid carrying hose (34, 36) extending along said flexible means for accessing, and a transporter (20) for moving said flexible means in the tube bundle, characterised in that said flexible means (24) for accessing comprises a plurality of separate, integrally formed hosebar supports (38), each comprising a pair of separate, longitudinally extending shapes (48) engaging the separate shapes (48) of adjacent hosebar supports (38) and together defining flexible, longitudinally extending strips (40, 42) and a bar (50) joining said pair of shapes, said bar having at least one correspondingly positioned aperture (52) with respect to apertures (52) in bars of the adjacent hosebar supports (38), the at least one fluid carrying hose (34, 36) extending along said plurality of hosebar supports (38) through the apertures (52) of said plurality of bars (50), and a pair of flexible support members (44, 46) each extending lengthwise through corresponding ones of each pair of the engaging separate, longitudinally extending shapes (48).
The system of Claim 1 in which said transporter (20) comprises a rack (84) and gears (82), said rack (84) extending along a drive rail (18) and said gears (82) being rotatably mounted on said transporter (20) to drive said transporter along said drive rail (18).
The system of Claim 2 in which said drive rail (18) is configured to mount said transporter (20) suspended from said drive rail (18).
The system of Claim 1 further including means for extending said flexible means (24) for accessing, said means for extending including sprocket wheels (74) positioned for engagement with a corresponding plurality of slots (54) formed in said flexible means for accessing.
The system of Claim 1 in which said at least one fluid carrying hose (34,36) includes a high pressure liquid hose (34) and a gas line (36).
The system as claimed in Claim 1 including a further fluid carrying hose (36) extending along said strips (40,42) through a further correspondingly positioned aperture (52) formed in each of said plurality of bars (50).
The system of Claim 6 in which said flexibile means (24) for accessing terminates in a nozzle block (56), said nozzle block having a group of high pressure orifices connected to said fluid carrying hose (34), and another high pressure orifice (62) connected to said further fluid carrying hose (36).
The system of Claim 1 in which said flexible means (24) for accessing includes an optical cable (32) extending along said strips through correspondingly positioned ones of the apertures (52) of said plurality of bars (50).
The system of Claim 1 in which said integrally formed hosebar supports (38) are formed of plastic.
The system of Claim 1 in which said integrally formed hosebar supports (38) are formed of nylon.
The system of Claim 1 in which each pair of separate, longitudinally extending shapes (48) have a bead shape with curved ends, the curved ends of each of the bead shapes (48) abutting the curved ends of adjacent ones of the bead shapes (48).